Light Always Moves the Same Speed

A long time ago, scientists wanted to figure out how fast the earth was moving through space. Their names were Michelson and Morley. They decided that they would try to figure this out by measuring the speed of light.

Think about it like this. Imagine you are in a rain storm, and the wind is blowing against your back. If you started running, the rain wouldn’t hit your back as hard. It would be travelling slower compared to you. Scientists would say that the rain was travelling slower relative to you.

And, of course, if you turned around and ran toward the rain, it would hit you even harder than if you stood still. Scientists would say that the rain was moving faster relative to you.

Back then, scientists thought that light acted like rain drops in a rain storm. They thought that if the earth was moving around the sun, and the sun was moving around the galaxy, they should be able to measure how fast they were moving through space. All they would need to do was measure how the speed of light “changed.”

And that’s exactly what they did. But they discovered something very strange.

The speed of light was the same no matter what. It didn’t matter which direction they were travelling around the sun.

This was very weird. If you ran through a rainstorm, you would expect the rain to hit you harder or lighter. It would be very strange if the rain felt exactly the same if you started running through it.

The scientists had discovered that light didn’t act like raindrops or anything else in the universe. No matter how fast you were moving, and no matter what direction you were heading, the speed of light was always the same. This was very confusing, and it took a man named Albert Einstein to figure out how this could be.

Time Slows Down

Einstein and another smart scientist named Hendrik Lorentz figured out that there was only one way to explain how things could work out this way. It was only possible if time slowed down.

Imagine what would happen if time slowed down for you. You wouldn’t know that you were moving and acting slower. Instead, it would seem like everything else was happening faster. Everything around you would be moving like a movie in fast-forward.

So now let’s imagine you’re in that rainstorm again. How could it be possible for the rain to feel exactly the same, even if you were running through it? Well, if you ran away from the rain, and your time slowed down, the rain would seem like it was speeding up. It would feel like it was hitting your back at exactly the same speed.

Scientists call this time dilation. No matter how fast you are moving, your time slows down so that you measure the speed of light to be exactly the same.

(This actually isn’t the whole story. The real world is even stranger. But we’ll talk more about that next week.)

Things Don’t Happen at the Same Time

Another thing that Einstein and Lorentz figured out was that if one person figures out that two things happen at the same time, another person might figure out that they didn’t happen at the same time.

The weirdest part is that both of them would be right.

This is another side effect of the fact that light always travels at the same speed.

Imagine you are standing in the center of your room, and you have set up a lamp right in the middle of the room. Now, pretend that the speed of light is very slow and you can see how it moves. Now, imagine you turn on the lamp.

As soon as you turn it on, the light will start spreading out. Since both walls are the same distance away, it will hit both walls at the same time. Scientists would say that the light hit both walls simultaneously.

Now imagine there’s a big window in your room, and your mom is driving past it. She will see something different. To her, it will look like your room is moving to the right.

When you turn on the lamp, she will see the left wall move toward the light as it spreads through your room. She will see the right wall move away from the light as it spreads through the room. She won’t see the light hit both walls at the same time. She will see it hit the left wall first, and the right wall second.

She would say that the light did not hit both walls simultaneously.

According to the theory of relativity, both of you would be right. From your perspective, the light hits both walls at the same time. From your mother’s perspective, it does not. There is nothing wrong with this. As long as you were doing your measurements correctly, both of you were right.

This is why scientists say that “simultaneity is relative.” If you measure two things to happen at the same time, somebody who is moving a different speed or a different direction will not measure them to happen at the same time.

This seems very weird to us because the speed of light is very fast and we move very slow compared to it. Since the speed of light is so fast, we don’t notice this, except in special experiments that scientists put together.

Fast Things Get Shorter

The last thing we’ll talk about today is how things that move very fast get shorter, another very strange side effect of the fact that the speed of light stays the same.

Again, let’s pretend that the speed of light is very slow. Imagine you are riding in a train, and you set up a lamp in the middle of your cart. Now pretend you turn on the lamp, just like you did in your room.

The light will spread out through the cart, and hit the front and back of it at the same time. You could measure the length of the cart by measuring how long it took for the light to reach the ends.

Let’s imagine that it takes light 1 second to travel 10 feet. (Light is much faster than this, of course!) Pretend that it took 1 second for the light to spread from the lamp to the ends of the cart. That would mean that the lamp was 10 feet from both ends of the cart. Since 10 + 10 = 20, that means your cart would be 20 feet long.

Now let’s imagine that your mom is outside the train, watching it drive past her. Remember, she will experience something different. The back of the cart will move toward the lamp, and the front of the cart will move away from it. So the light won’t hit the front and back of the cart at the same time. It will hit the back of the cart first, and the front of the cart second.

When we want to measure how long something is, we need to know where the front and back are at the same time. So if your mom didn’t know any better, she would say that you made a mistake.

In fact, she would say that your measurement was too long. Even though the light takes less time to reach the back of the cart, it takes much more time to reach the front of the cart. The total distance you measured would be longer than the actual distance she would measure.

But, again, according to the theory of relativity, both of you are actually right.

You will measure the length of the cart to be one way, and your mom will measure it to be shorter. There is nothing wrong with this. It is just the way the world works.

So that is why when an object moves close to the speed of light, it starts to become shorter and shorter.

But remember, that’s only the way that you measure it if the object is moving very fast compared to you. If you were inside a rocket ship that was travelling close to the speed of light, you wouldn’t feel any different. You wouldn’t feel like time was ticking slower, or that the front and back of the ship were moving closer together. That is just what other people would measure if they were watching you from a planet as you soured past them.

But wait a minute. If you were in your rocket ship, it would look like all the planets and stars were flying past you at close to the speed of light. Shouldn’t you measure their time to slow down, and their lengths to shrink and get shorter?

Yes, it turns out. If this is confusing to you, don’t worry. It was very confusing to scientists as well. It took Einstein to figure out the solution to this. (Everything else we’ve talked about was also figured out by Hendrik Lorentz before Einstein put together the complete theory of relativity.) This is called the twin paradox, and we will talk about it next week if you’re interested. (Click here to read Part 2.)

If you want to learn more, ask your parents if they’ll order this book for you: